DE4214336C2 - Toning sheet for wind instruments - Google Patents

Abstract

PCT No. PCT/EP93/00996 Sec. 371 Date Nov. 4, 1994 Sec. 102(e) Date Nov. 4, 1994 PCT Filed Apr. 24, 1993 PCT Pub. No. WO93/22761 PCT Pub. Date Nov. 11, 1993The invention is directed to a sound-producing reed for wind instruments which is made from fiber-reinforced plastic and is characterized in that the basic material of the plastic is stabilized by at least one unidirectional layer (27, 29) having fiber strands (31) extending in the longitudinal direction of the reed (7), some of these strands (33) having different material characteristics for the purpose of damping the vibrations of the reed (7).

Description

The invention relates to a toner-stimulating sheet for Wind instruments made of fiber-reinforced plastic.

Numerous wind instruments are also available with one Tongue designated, sound-generating sheet, among other things, for example saxophones and clari nice. These instruments have a mouthpiece on the in a suitable manner, for example by means of a ligature, the leaf is attached. It also gives instruments with double reeds for example oboes and bassoons.

Basically, the manufacture of such toning sheets of cane wood are used. Wood leaf ter have the disadvantage that their durability is very limited and that their production is very expensive is. In addition, each wooden sheet must be imported be: Every time the wood leaf on the mouth piece of the instrument is attached about a break-in period of about half Hour. During this time, they change  Playing characteristics of the wooden sheet due to the Moisture absorption. The natural material is also very sensitive. Especially in the area of Leaf tip often tears, so that Sheet becomes unusable.

It is also known to make clay-producing leaves To manufacture plastic. The one to be generated with it However, sound in no way reaches the quality that can be achieved with wooden leaves. Moreover, is the surface structure at least takes getting used to, so for this reason many players like this Reject leaves.

Finally, it is known from FR 2 626 400 A2 toner-stimulating sheets made of fiber-reinforced plastic to manufacture. The achievable sound qualities were still such that numerous players saw forced by wind instruments, wooden leaves to use with the disadvantages mentioned.

In contrast, it is an object of the invention toner-stimulating blade for wind instruments made of fiber-reinforced To create plastic whose sound qualities are significantly improved Play characteristics very similar to those of wooden leaves comes close and its surface structure for the User is very pleasant.  

This task is done on a toner-stimulating sheet according to the preamble of claim 1 using the in resolved this claim features. Thereby, that the sheet of several layers with different Material properties is built up, where at least one layer is provided, the fiber strands running unidirectionally in the longitudinal direction has, with individual fiber strands differing Have material properties and hollow fibers include a very good sound of the toner-stimulating sheet, while at the same time Durability is much better than conventional ones Plastic and wood sheets. The fiber strands have been particularly influencing proven the sound properties of the toner-stimulating sheet. Furthermore, it is a blank comprising hollow fibers easy to process for one sheet.

In another embodiment of the sheet is the layer of unidirectional fiber strands as Carbon fiber scrim formed. Such Layer is relatively easy to manufacture. About that a sheet designed in this way also stands out through particularly good sound qualities.

In another preferred embodiment of the toner sheet is in addition to one Carrier layer, the fibers of which are preferably in the right There are angles to each other, at least one support layer provided, which in turn has fibers, the fibers of which are preferably at right angles to one another run and offset to the fibers of the carrier layer  are arranged. Because of this structure the sheet has a high stability and therefore consistent sound characteristics. The one at the Wear occurring will also be very kept low. Especially in the area of front edge of the leaf - the leaf tip due to the offset Fibers from support and carrier layers prevent cracks the.

An embodiment is also particularly preferred form of the leaf, with the underside of the Carrier and / or support layers are arranged and where the layer with unidirectional fiber strands resting on these layers. The sub side of the sheet is very stable and twisted stiff enough so that a good circulation guaranteed on the mouthpiece of the wind instrument is. On the other hand, the or stabilizing layer Location of unidirectional fiber strands the sound quality leaf effects positively influenced.

Finally, an embodiment is particularly preferred Example of a toner-stimulating sheet in which at least in the area of the edge of the leaf tip there are two layers, the parting plane like this is arranged that this approximately in the middle between the top and bottom of the leaf margin is not. This ensures that in the be particularly sensitive edge area, which is often a tears, there are at least two layers, the locations of which are the top and  Underside of the leaf tip result. The fibers of the resulting layers are offset or ver turns to each other so that tearing of the tongue edge with particularly high security is to be locked.

Further refinements of the invention result from the other subclaims.

The invention is based on the drawing tion explained in more detail. Show it:

Fig. 1 shows schematically a mouthpiece of a Blasin strument in side view;

Fig. 2 is a longitudinal section through the front part of a sheet;

Fig. 3 is a plan view of the front area of a sheet and

Fig. 4 shows a cross section through the rear loading area of a sheet.

Tone-inducing leaves, as described below can be written for wind instruments various types can be used, especially for Saxophones and clarinets. With these instruments one sheet at a time on the mouthpiece of the In struments attached that there is almost an opening is closed, then the leaf in its rear area, i.e. in the area of its shaft with a suitable tensioning device, preferably a ligature, so attached to the mouthpiece  is that the front end, the tip of the leaf Leaves free above the mouthpiece opening can swing.

Toning leaves described below A type can also be used with wind instruments find that have a double sheet at for example with oboes and bassoons. With these In instruments are two sheets of toner each other arranged opposite each other so that when blowing the leaves of an air column vibrate, so one inside the wind instrument vibrating column of air arises, the length of which Open and close the designated opening can be varied in the wind instrument that tones of different heights are produced.

The schematic illustration of FIG. 1 shows a side view of a wind instrument 1, wherein in the loading reaching a mouthpiece 3 by means of an apparatus as Spann serving ligature 5, a toner regendes sheet 7 is clamped so that the sheet in the region of its shaft 9 fixed to the Mouthpiece 3 of the wind instrument 1 is pressed while the opposite end, the blade tip 11 of the blade 7 , can swing over an opening in the mouthpiece 3 when the wind instrument is played. In the game shown here Ausführungsbei the ligature is exemplarily formed as the ring 3 spanning ring, in the sen underside two clamping screws 13 can be screwed by means of a thread so that they press the shaft 9 of the blade 7 against the underside of the mouthpiece 3 .

The design of the mouthpiece depends on the type of wind instrument and ge if necessary also according to its pitch.

FIG. 2 shows a greatly enlarged longitudinal section through a toner-stimulating sheet 7 , as shown in FIG. 1. The sectional view makes it clear that at the opening in the mouthpiece 3 shown in FIG. 1, the underside 15 of the blade 7 closing two layers 17 and 19 are present, of which the lower layer is referred to as the support layer 17 and the overlying layer as the support layer 19 . The dividing plane 21 between the carrier and the support layer is indicated by a dashed line.

In the exemplary embodiment shown here, the carrier layer 17 runs together with the support layer 19 parallel to the underside 15 of the sheet 7 . In the foremost area of the blade tip 11 , in the loading area of the edge 23 , there are two layers, namely the carrier layer 17 and the support layer 19 , the parting plane 21 of which is arranged such that this is located approximately halfway between the bottom 15 and the top 25 of the leaf tip is located.

In the game Ausführungsbei shown in Fig. 2, a support layer 17 and a support layer 19 is provided. However, the number of these layers can be adapted to the size of the sheet and can also be determined depending on the desired sound qualities.

Over the carrier and support layers are in particular in the right area of the blade 7 , that is, in the area of the shaft 9 , several superimposed damping layers 27 and 29 can be seen , the number and thickness of which in turn can be selected depending on the type of sound-generating sheet and the desired sound qualities are.

The top view shown in Fig. 3 on the front end of the blade 7 shows that the damping layers 29 and 27 end at a distance from the edge 23 of the blade tip 11 , and that in the foremost loading area of the blade 7, the support layer 19 is visible.

The - albeit schematic - representation of the sheet 7 in Fig. 3 shows that the damping layers uni directional 7 strands have approximately in the longitudinal direction of the sheet. A hatching indicates that individual fiber strands of the damping layers 29 and 27 are made of a different material. In Fig. 3 hollow fiber strands 33 are indicated within the individual damping layers. Instead of the strands formed from hollow fibers, fiber strands made of glass or aramid fibers can also be used.

Because the thickness of the blade 7 decreases more or less continuously starting from the shaft 9 to the front edge 23 of the tongue 11 (see FIG. 2), the individual layers 27 and 29 end at an ever greater distance from the edge 23 of the blade tip 11 , the distance between the upper layers and the edge 23 being greater than that of the lowermost layer 27 . This means that the fiber strands running in one direction of the damping layer 27 lying directly on the support layer 19 extend almost to the front edge 23 of the sheet tip 11 .

Depending on the total thickness of the sheet and the desired sound or sound qualities, the thickness gradient shown in Fig. 2 can be chosen more or less, so that accordingly the individual damping layers at a more or less large distance from the front of the edge 23 of sheet 7 end.

In the plan view of FIG. 3 is indicated, that is on the upper side of the sheet location, an attenuation applied in the subsequent to the blade tip loading reaching 35, the width of which is ge here chosen such that their longitudinal sides not quite to the lateral longitudinal edge of the Reach sheets and the rear transverse side is approximately triangular and the front transverse side pointing to the leaf tip is approximately trapezoidal. Shape and expansion of the damping layer 35 are in turn varied depending on the size of the sheet and the desired sound quality. It is also possible to introduce the damping layer between two layers, in which case, however, the front end of the damping layer 35 , which points in the direction of the edge 23 of the tongue 11 , is removed with the adjacent layers, so that the damping layer with that between the layers two separating layers adjacent to the layers ends.

In the illustration in FIG. 3, however, it is assumed that the damping layer is applied to the top of the sheet, preferably is glued to it, and is designed as a film, in particular as a self-adhesive film.

The individual damping layers 27 and 29 , which consist of carbon fiber scrims, may have transverse stabilization strands extending transversely to their fiber strands 31 and 33 , which are not shown in FIGS . 2 and 3. These stabilizing strands can in turn comprise hollow and aramid, carbon fibers or even glass fibers. The strands serve to additionally stabilize the individual layers or the sound-generating sheet 7 .

Finally, a cross section through the region of the shaft 9 of a blade 7 is shown in a highly schematic manner in FIG. 4. It is clear that the underside 15 of the sheet 7 is flat, and that the two lowest layers, the support layer 17 and the support layer 19 , as well as the parting plane 21 thereof, run parallel to the underside 15 of the sheet 7 . The above-mentioned damping layers 27 and 29 are located above the carrier or support layer. In addition, a cover layer 37 can also be provided in the region of the shaft 9 .

The sectional view shows that the top of the blade 7 has a curvature in the region of the shaft 9 . It is possible that the top of the cover layer 37 follows the curvature of the rest of the sheet or is flat. With a flat configuration of the top of the cover layer 37 , there is a particularly good contact surface for the clamping screws 13 of the ligature 5 (see FIG. 1). A blade 7 formed in this way can therefore be particularly securely attached to the mouthpiece of a wind instrument. The sheet can also be attached in another way, for example by means of a textile tape on the mouthpiece of an instrument, the design of the shaft 9 being adaptable to the fastening means in each case.

The toner-stimulating sheet 7 described with reference to FIGS. 1 to 4 consists of plastic. Several fiber layers are integrated in a plastic mass or matrix made of, for example, epoxy resin or phenolic resin.

The base of the sheet 7 forms a carrier layer 17 , which has fiber strands running at an angle of 90 ° to one another, which can only be placed over one another or interwoven. The angle between the fiber strands can also be chosen to deviate from 90 °. Depending on the size of the sheet and its sound quality, several support layers can also be used. The fiber bundles of the carrier layer preferably consist of carbon fibers. For example, each layer is 12/100 mm thick. The width of a fiber bundle may be approximately 1 mm.

A support layer 19 is arranged above the carrier layer 17 and can in principle be constructed identically to the carrier layer. However, the orientation of the fiber bundles of the support layer is changed compared to the orientation of the fiber bundles of the carrier layer. The fiber bundles of the support layer 19 may include, for example, an angle of 90 ° to one another and 45 ° to the fiber bundles of the carrier layer. The fiber bundles of the support layer can also have angles other than 90 ° to one another. This results in layers lying one above the other, the fiber strands of which have different angles to one another within a layer and from layer to layer. The thickness of the support layer, like that of the support layer, can be varied depending on the overall thickness of the sheet and its sound qualities. The width of the fiber bundle, which is about 1 mm here, can also be varied.

The thickness of the toner-stimulating sheet 7 is in the area of the edge 23 of the tip 11 of the blade about 1/10 mm. The carrier and support layers are arranged in such a way that at least one carrier and support layer is present, the parting plane 21 of which is arranged approximately in the middle of the edge of the sheet, as was indicated in FIG. 2.

There are over the carrier and support layers several layers running unidirectionally, in Longitudinal direction of the sheet of aligned fiber strands, preferably as carbon fiber scrim are trained. Individual fiber strands are through Hollow fibers, for example osmosis fibers replaced. Fibers can also be used in dialysis be used. If necessary, different Combined hollow fiber types.

Each hollow fiber strand can, for example, 30 hollow have fibers, number and width of the hollow fiber however, strands are variable, including the number of individual, provided within these strands Fibers. In the embodiment shown here the hollow fiber strands are just as wide sets how the fiber strands of the carbon fiber scrim. Due to the number of hollow fiber strands, the Dampening the movement of the toner sheet and so that its sound can be influenced.

The toner-stimulating sheet is produced by that the individual support, support and damping layers on top of each other in the plastic matrix can be embedded. The basic body can be used Hardening of the plastic mass to be heated. The Curing can also be done under pressure. The Her position of the initial form or The basic body of the toner-stimulating sheet is known.

After the production of the blank of the toner-stimulating sheet, all layers run more or less parallel to one another. In addition, the top layer 37 mentioned in FIG. 4 can also be applied as the top layer, which in turn can be a carbon fiber fabric, the fiber bundles of which in turn run at an angle of approximately 90 ° to one another. However, the angle of these fiber strands can also be varied, and it is also possible to provide a plurality of covering layers lying one above the other. The cover layer 37 preferably consists of the same number of layers as the carrier and support layers. It is only used to create a symmetry so that the blank does not warp after the matrix has hardened.

After the production of the blank, the blade tip is worked out by a removal process, for example by grinding, by removing the material of the blank in the region of the so-called stitch, so that the thickness of the blade 7 starting from the shaft 9 to the front edge 23 the blade tip 11 decreases more or less continuously. The thickness profile, which results, for example, from the longitudinal section according to FIG. 2, can be selected as in conventional toner-stimulating sheets and adapted to the desired sound properties.

In addition, the surface curvature can be worked out on the top 25 in the area of the shaft 9 . However, in order to give the blank of the sheet 7 an optimal contact surface for further processing, the underside 15 is ground flat. This is particularly important for the processing of the very fine blade tip 11 , because this would otherwise yield during the subsequent grinding process and could thus maintain an undefined thickness. It is also possible that the blade will break out when grinding.

After the top of the blade 7 has been ground off and the blade tip has been worked out, a damping layer 35 can be applied in the region of the top of the blade tip. The material of this layer can be freely selected depending on the desired sound qualities. For example, a self-adhesive plastic film can be applied. The shape of the damping layer 35 can in turn be selected depending on the size and the sound qualities of the toner-generating sheet. By varying the size and arrangement of the damping layer, characteristic tonal qualities can be given to the toner-stimulating sheet, as the individual player desires.

Instead of the hollow fibers, aramid fibers can also be used the damping layers are introduced. It he however, there is a somewhat rougher upper surface of the leaf. This difference from toner raining leaves with hollow fibers in the damping can layer through a larger cushioning layer partially balanced.

It is of course also possible to use the coal fibers of the carbon fiber scrim of the damping layer through both hollow and aramid fibers to replace, ie a combination of hollow and Introduce aramid fibers into the cushioning layer.  

The hollow or aramid fibers provide the damping of the vibrations of the sound-generating Leaf, while the carbon fibers research this impart stiffness.

In a preferred embodiment of a toner-stimulating sheet for an alto saxophone, an embodiment has proven itself in which approximately 7 to 10 damping layers, a support layer and a carrier layer have been provided. In this sheet, the thickness in the area of the shaft 9 is approximately 1.7 mm.

The number of layers must be toner-inducing Scrolls for tenor, baritone and bass saxophones be raised, since the sheet is thicker in this case must be trained. With soprano and soprano saxophones must match the thickness of the sheet be humiliated.

In all cases, the underside 15 of the blade 7 is ground flat, with the carrier layer 17 being partially removed. In the finished sheet 7 , the top of the support layer 19 is also removed in the region of the edge 23 by the removal or grinding process, so that the parting plane 21 between the support and support layer is approximately in the middle between the top 25 and the bottom 15 of the blade tip 11 comes to rest.

Due to the two layers with staggered fiber fabrics, the edge 23 of the leaf tip 11 is given a special stability, so that cracks can be avoided here with a high degree of certainty.

To influence the damping and thus sound properties of the sheet can be in one or more layers of so-called microballoons in the resin the plastic matrix. It is it is also possible to just select some areas of the To provide layers with such microballoons. The materials for the microballoons - for example as inorganic silicates or glass, cork, fiber materials or the like - become dependent the desired properties of the sheet elects.

The sound and damping properties of a leaf can also be influenced by the fact that Resin of the plastic matrix with a flexibilizer is provided, with the introduction of the Flexibilizer in one or more layers or even in some areas of one or can be done in multiple layers.

The properties of the leaf can also be there are influenced by the fact that resins, lacquers and / or Subsequent adhesives on the top and / or bottom of the Surface of the sheet can be applied. Depending on the desired sound characteristics can be a continuous layer applied or only individual areas of the top and bottom of the Leaf can be wetted.  

In the manufacture of the plastic matrix especially methyl methacrylate resin solutions defends them, for example as a hardener, the Di benzoyl peroxide and as activator N, N-diethanol-P- Toluidine is buried. Furthermore, it is also possible, the different resins pigments and / or - to reduce density - add fillers, for example, microballoons made of inorganic sili cater for or fibrous or powdery substances put. Finally, the plastic matrix can still Flexibilizers are added, which are also the Affect damping and sound properties.

Basically, the bottom layers of the Leaf, the support and the support layer, unung dampened. But also here can be leg flow of sound and damping properties Fle xibiliators introduced and / or other additive fabrics, microballoons or fibrous fillers beige be added. These can vary from layer to layer Layer varies and possibly only be be brought in abundantly.

It was stated above that the parting plane between the support and carrier layers should be arranged as far as possible in the middle of the outermost edge of the sheet 7 . However, instead of the layers described above, it is also possible to use a carbon fiber fleece which has no defined fiber orientation. In this case, the grinding process in the area of the blade tip can be carried out independently of any parting plane, so that the manufacture of the blade is simplified. The higher fiber content of the fleece also results in increased stability of the sheet.

The plastic matrix of the carbon fiber fleece can just like the other areas of the leaf, for Apply a resin to the damping setting which is characterized by increased damping properties distinguished.

Finally, it should be noted that the lower ones Layers of the leaf but also others Layers can be formed as hybrid fabric, which is characterized in that in a company Carbon fiber can be used while in a different fiber direction, that with the first Direction can include any angle Aramid and / or glass fibers are used. Be The sound characteristics of the Use of carbon fibers for the longitudinal fibers of the Leaf.

From the above, it can be seen overall that carbon, aramid and / or glass fibers in all Layers of the sheet can be used.

The toner sheet described here draws is characterized by a very long shelf life. Due to the particularly flat underside, the Play can not swell very well consistent sound qualities even with longer ones Achieve use of the sheet. Moreover, there is one Do not import the sheet at the beginning of use required. One thing was needed for wooden leaves  certain swelling of the wood fibers before that Sheet achieved the desired sound characteristics would have. This is the case with the toner-stimulating leaf type described here not possible and also not required. The desired sound characteristics are immediately the first time you play the hand already reached.

Claims (18)

1. Toner-stimulating sheet for wind instruments made of fiber-reinforced plastic, characterized in that the sheet is constructed from several layers with different material properties, at least one layer ( 27 , 29 ) being provided, the unidirectional, in the longitudinal direction of the sheet ( 7 ) extending fiber strands ( 31 ), wherein individual fiber strands ( 33 ) have different material properties and comprise hollow fibers. 2. Sheet according to claim 1, characterized in that the individual strands ( 33 ) comprise glass and / or aramid fibers. 3. Sheet according to one of claims 1 or 2, characterized in that the layer ( 27, 29 ) unidirectional fiber strands ( 31 , 33 ) has carbon fibers. 4. Sheet according to one of claims 1 to 3, characterized in that the layer ( 27 , 29 ) unidirectional fiber strands ( 31 , 33 ) is designed as a carbon fiber scrim. 5. Sheet according to one of the preceding claims, characterized in that the layer ( 27 , 29 ) with unidirectional fiber strands ( 31, 33 ) has transverse to these stabilizing strands. 6. Sheet according to claim 5, characterized in that as stabilizing strands carbon fibers, hollow fibers, Aramid fibers and / or glass fibers are used become. 7. Sheet according to one of the preceding claims, characterized in that at least one carrier layer ( 17 ) made of fiber-reinforced plastic is provided, the fibers of which preferably run at right angles to one another. 8. Sheet according to claim 7, characterized by at least one support layer ( 19 ) made of fiber-reinforced plastic, the fibers of which preferably run at right angles to one another and in particular are arranged offset to the fibers of the carrier layer ( 17 ). 9. Sheet according to one of claims 7 or 8, characterized in that carbon fibers, hollow fibers, aramid fibers or glass fibers are used as the support layer ( 19 ) and / or carrier layer ( 17 ). 10. Sheet according to one of claims 7 to 9, characterized in that on the underside ( 15 ) the carrier layer ( 17 ) and / or the support layer ( 19 ) is arranged, and that the layer with unidirectional fiber strands ( 27 , 29 ) over these layers. 11. Sheet according to one of the preceding claims, characterized in that its thickness decreases starting from a shaft ( 9 ) in the region of a tapping up to the front edge ( 23 ). 12. Sheet according to one of the preceding claims, characterized in that in the region of the shaft ( 9 ) the thickness of the sheet ( 7 ) decreases from its imaginary center line to the longitudinal edges thereof. 13. Sheet according to one of the preceding claims, characterized in that in the region of the shaft ( 9 ) 7 superimposed damping layers ( 27 , 29 ) with unidirectional fiber strands ( 31 , 33 ) and underlying support layers ( 19 ) and a lowermost carrier layer ( 17 ) are provided are. 14. Sheet according to one of the preceding claims, characterized in that the bottom and / or at least the area of tapping a removal process preferably a grinding process have been subjected. 15. Sheet according to one of the preceding claims, characterized in that at least two layers ( 17 , 19 ) are provided in the region of the edge ( 23 ) of the sheet tip ( 11 ), the parting plane ( 21 ) of which approximately in the middle between the upper side ( 25 ) and the underside ( 15 ) of the blade tip is arranged. 16. Sheet according to one of the preceding claims, characterized in that its underside ( 15 ) is flat and that the carrier layer ( 17 ) extends over the entire underside of the sheet ( 7 ). 17. Sheet according to one of the preceding claims, characterized by a damping layer ( 35 ) which is preferably arranged on its upper side ( 25 ) in the region of the sheet tip ( 11 ). 18. Sheet according to claim 17, characterized in that the damping layer ( 35 ) is formed by a preferably adhesive film.